Glucose, Glucose Transporters And Blastocyst Formation In The Mouse
Funder
National Health and Medical Research Council
Funding Amount
$281,650.00
Summary
Embryo-based biotechnologies have the potential to improve human reproductive health, notably in treating infertility by In vitro fertilisation (IVF). They are also central to the future use of embryonic stem cells for human tissue replacement. This project investigates the molecular mechanisms controlling one of the earliest differentiations in the growth of the embryo. Using the mouse as an experimental model it will investigate the importance of several factors in the changes which set up the ....Embryo-based biotechnologies have the potential to improve human reproductive health, notably in treating infertility by In vitro fertilisation (IVF). They are also central to the future use of embryonic stem cells for human tissue replacement. This project investigates the molecular mechanisms controlling one of the earliest differentiations in the growth of the embryo. Using the mouse as an experimental model it will investigate the importance of several factors in the changes which set up the placenta and fetus as seperate tissues in the very early embryo. A key focus is the supply of glucose to the newly fertilised embryo and how important this glucose supply is for the survival of the embryo. Moreover there is great interest in the possibility that metabolic events in utero can contribute to the development of diseases in later life, notably, coronary heart diease, stroke, high blood pressure and non-insulin dependent diabetes. The results from these studies will contribute to our understanding of why some couples are infertile, lead to improved management of infertility by diet and invitro fertilisation procedures. It will also be of benefit in dietary advice to women with diabetes mellitus, seeking to have children. The adenoviral strategy for gene delivery into early mouse embryos may in the long term also find wide clinical application in the treatment of genetic defects at the very earliest stages in development and as such is of enormous potential benefit in the management of both animal and human reproduction.Read moreRead less
I am a reproductive biologist whose research is focussed around understanding how the early events of conception and embryo development are controlled. Critical aspects of my research are to determine the consequences to pregnancy and adult health if the
Oxygen, Oxidative Phosphorylation And Regulation Of Embryo Development.
Funder
National Health and Medical Research Council
Funding Amount
$141,096.00
Summary
There is concern that human infertility treatment requiring the growth of embryos in the laboratory, as applied in human IVF, may cause problems during fetal development or even possibly lead to health problems much later in life as an adult. In particular, many clinics are now growing human embryos outside the body for several days longer (to select the best embryos for transfer) than what occurred a decade ago. This concern is based on the evidence that the environment in which an embryo grows ....There is concern that human infertility treatment requiring the growth of embryos in the laboratory, as applied in human IVF, may cause problems during fetal development or even possibly lead to health problems much later in life as an adult. In particular, many clinics are now growing human embryos outside the body for several days longer (to select the best embryos for transfer) than what occurred a decade ago. This concern is based on the evidence that the environment in which an embryo grows in has an impact on the way in which some genes are switched on and off. Normal on-off switching at appropriate times during early development should lead to healthy offspring. Failure to turn off or on, or inappropriate timing, may lead to consequences that manifest themselves later in development. We believe that oxygen concentration and the activity of mitochondria, the organelles of cells that converts oxygen into energy, are key regulators in turning on and off genes during early embryo development. This is because we have shown that, in embryos of a species that is metabolically similar to the human embryo, oxygen concentration and mitochondria activity need to change as the embryo grows for optimal development in the laboratory. In other mammalian cells, oxygen and mitochondria activity are known to turn on or off several particular genes, known as transcription factors. Transcription factors are genes which regulate other genes. Therefore, transcription factors are good candidates as regulators of early embryo development. The present project aims to determine if factors such as changing oxygen concentration and mitochondria activity during laboratory growth of embryos affects the way in which these transcription factors turn on and off. If we find this is true, the way in which human embryos are grown in the laboratory needs to be examined carefully to minimize the risk of possible long-term consequences to the resulting fetus.Read moreRead less
Understanding The Determinants Of Human Oocyte And Embryo Health
Funder
National Health and Medical Research Council
Funding Amount
$252,761.00
Summary
This project will address key questions involving how the human egg and embryo maintain their ability to develop into a healthy fetus. In recent years there have been significant advances in our understanding of how animal oocytes grow and become competent as well as an increased understanding of how the animal embryo maintains its viability in culture. Currently there is little information as to how the human oocyte and embryo develops. This study will address the current lack of knowledge by e ....This project will address key questions involving how the human egg and embryo maintain their ability to develop into a healthy fetus. In recent years there have been significant advances in our understanding of how animal oocytes grow and become competent as well as an increased understanding of how the animal embryo maintains its viability in culture. Currently there is little information as to how the human oocyte and embryo develops. This study will address the current lack of knowledge by extending the information gathered in animal models to establish how the human oocyte communicates with its surrounding cells and how this communication is important for development. We will also study how the developing embryo maintains its physiology and metabolism and the relationship between the ability to control metabolic balance and viability will be established. All of the questions outlined in this proposal can be performed without disturbing the oocyte and developing embryo by analysing the surrounding cells and the spent media. Therefore, all of these questions can be answered non-invasively. The outcome of this proposal will be an increased understanding of how the physiology and development of the human oocyte and embryo is maintained. However, importantly this data will then provide information as to the relationship of these parameters to developmental competence. Therefore, it will be possible to establish a range of markers that can be used to predict the developmental competence of a human embryo. Currently multiple embryos are routinely transferred in an IVF cycle resulting in an increase in multiple gestation pregnancies and their associated complications. The information generated in this study will provide information enabling markers to be used to identify the most viable embryo from a cohort, which is essential if single embryo transfer is to be universally adopted in an IVF program.Read moreRead less
Is Calcium part of the mechanism used in glucose signalling in embryogenesis. A vital stage in the development of the embryo is formation of the blastocyst about 4 days after conception. For this to happen the embryo must receive glucose from the mother. We believe that rather being used by the embryo to generate energy, this glucose acts as a signal to switch on the developmental pathway leading to blastocyst formation. Without this signal there is no blastocyst and the pregnancy fails. The pr ....Is Calcium part of the mechanism used in glucose signalling in embryogenesis. A vital stage in the development of the embryo is formation of the blastocyst about 4 days after conception. For this to happen the embryo must receive glucose from the mother. We believe that rather being used by the embryo to generate energy, this glucose acts as a signal to switch on the developmental pathway leading to blastocyst formation. Without this signal there is no blastocyst and the pregnancy fails. The project investigates this signal mechanism. The results will advance understanding of the mechanisms regulating development and in particular link the mother's nutritive status to her fertility during very early pregnancy.Read moreRead less
Characterisation Of Cumulus Cell Molecular Mediators Of Oocyte Health
Funder
National Health and Medical Research Council
Funding Amount
$451,896.00
Summary
Many women are poorly fertile because of poor egg quality due to age, disease and lifestyle. IVF can assist, but requires large doses of hormone, which can lead to significant health risks. IVM is an alternative lab technique to IVF, but has very poor success. We discovered that synthetic proteins copied from recently discovered egg proteins can be added to the egg and substantially increase IVM success. Answering why will further will aid treatment for infertile women
Chemical principles underpinning a spermostatic-microbiostatic agent capable of preventing pregnancy and the spread of sexually transmitted disease. This project explores the development of a method for simultaneously controlling fertility while preventing the spread of sexually transmitted diseases. A novel aspect of the approach, that will dramatically influence product development, is that the active principles will only be generated on contact with seminal plasma.
Discovery Early Career Researcher Award - Grant ID: DE120100304
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Biomimetic systems for species preservation and fertility restoration. Using a novel 3-D culture system the project will examine the biomechanics of ovary follicle and egg development in vitro, generating new knowledge with directly translatable research outcomes. In vitro egg production has implications for human fertility and threatened species preservation, significantly benefitting health and biodiversity in Australia.
We propose to determine if a recently discovered biological mechanism plays crucial roles in the development of eggs and sperm. To achieve this, we will remove or mutate this pathway specifically in developing eggs and sperm , then examine the effect. Preliminary results indicate that the mechanism does play important roles mutated eggs fail to complete maturation. These studies will tell us more about what makes a healthy egg and sperm, and are relevant to female and male fertility.